Posttranscriptional regulation of gene expression in eukaryotes

真核生物基因表达的转录后调控

基本信息

批准号：
7828752
负责人：
KARSTEN WEIS
金额：
$ 49.15万
依托单位：
UNIVERSITY OF CALIFORNIA BERKELEY
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-09-30 至 2011-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7828752
关键词：
Address Affect Amino Acids Area Biological Assay Cell Death Cell physiology Cells Classification Code Defect Development Disease Environment Eukaryota Eukaryotic Cell Event Gene Expression Gene Expression Regulation Genes Genetic Genetic Transcription Genetic Translation Genome Growth Half-Life Individual Label Laboratories Life Malignant Neoplasms Maps Mass Spectrum Analysis Measurement Measures Mediating Messenger RNA Methods Molecular Monitor Nucleotides Pathway interactions Pattern Physiologic pulse Play Post-Transcriptional Regulation Process Production Proteins Proteome RNA RNA Sequences Regulation Role Running Stable Isotope Labeling System Technology Time Transcriptional Regulation Translations acute stress biological research cell growth cell type human disease insight mRNA Decay mRNA Stability molecular dynamics novel prevent programs protein degradation public health relevance research study response

项目摘要

DESCRIPTION (provided by applicant): This application addresses broad Challenge Area (06) Enabling Technologies and specific Challenge Topic, 06-GM-112: Molecular and Cellular Dynamics Technologies. A central problem in biological research is to understand how the genome is interpreted to determine the large diversity of organismal form and function. In addition, it is critical to identify misregulations that can occur during the interpretation of the genetic information in order to dissect and prevent the development of human diseases. While it has been well established that many important steps in the regulation of gene expression occur at the level of transcription, it has become increasingly clear that posttranscriptional processing is also essential for the precise control of gene expression in eukaryotic cells. Examples include the discovery of RNA-mediated silencing pathways that control mRNA translation or decay and play critical roles during organismal development or during the development of diseases such as cancer. However, in contrast to our excellent understanding of transcriptional control mechanisms, very little is still known about post-transcriptional regulatory programs. This is in part due to the lack of technologies that would enable us to analyze post-transcriptional control steps in a dynamic and non-invasive fashion. In this application, we will address this challenge and propose the development and application of novel labeling methods that will allow us to measure on a system-wide level the turnover of individual RNAs and proteins with high sensitivity and without perturbation of the cellular environment. For the first time, this will allow us to integrate changes that occur in transcription with measurements of mRNA stability, translation and protein turnover. Together, this will allow us to develop a comprehensive overview of the regulation of gene expression under various growth conditions and in different cell types. In the long run, my laboratory will explore new paradigms that emerge from these studies and will elucidate the molecular mechanism underlying novel regulatory responses. These studies will provide critical insight into the fundamental principles that determine the cellular dynamics of gene expression patterns and help us to understand defects that occur in human diseases. PUBLIC HEALTH RELEVANCE: In all eukaryotes, the tight regulation of gene expression is essential for cells to control proliferation, differentiation or development, and errors in any step of the gene expression program can have severe consequences leading to cell death or disease. A critical step in the control of gene expression is the control of mRNA and protein abundance by the regulation of their decay. Therefore, a better understanding of the regulation of mRNA and protein turnover is essential both for the understanding of fundamental cellular processes and the development of novel therapies for human diseases.

描述（由申请人提供）：本申请解决了广泛的挑战领域 (06) 支持技术和特定挑战主题 06-GM-112：分子和细胞动力学技术。生物学研究的一个中心问题是了解如何解释基因组以确定生物体形式和功能的巨大多样性。此外，识别遗传信息解释过程中可能发生的错误调节对于剖析和预防人类疾病的发展至关重要。虽然已经明确基因表达调控的许多重要步骤发生在转录水平，但越来越清楚的是，转录后加工对于真核细胞中基因表达的精确控制也至关重要。例子包括发现RNA介导的沉默途径，该途径控制mRNA翻译或衰变，并在有机体发育或癌症等疾病的发展过程中发挥关键作用。然而，与我们对转录控制机制的深入了解相反，我们对转录后调控程序知之甚少。这部分是由于缺乏使我们能够以动态和非侵入性方式分析转录后控制步骤的技术。在此应用中，我们将解决这一挑战，并提出开发和应用新型标记方法，使我们能够在全系统水平上高灵敏度地测量单个 RNA 和蛋白质的周转，且不会干扰细胞环境。这将使我们第一次能够将转录中发生的变化与 mRNA 稳定性、翻译和蛋白质周转的测量整合起来。总之，这将使我们能够全面了解各种生长条件和不同细胞类型下的基因表达调控。从长远来看，我的实验室将探索这些研究中出现的新范式，并阐明新调控反应背后的分子机制。这些研究将为决定基因表达模式的细胞动力学的基本原理提供重要的见解，并帮助我们了解人类疾病中出现的缺陷。公共健康相关性：在所有真核生物中，基因表达的严格调控对于细胞控制增殖、分化或发育至关重要，基因表达程序任何步骤的错误都可能产生严重后果，导致细胞死亡或疾病。控制基因表达的一个关键步骤是通过调节 mRNA 和蛋白质的衰减来控制它们的丰度。因此，更好地了解 mRNA 和蛋白质周转的调节对于了解基本细胞过程和开发人类疾病的新疗法至关重要。